Chemiluminescence Detector with a Serpentine Flow Cell - Analytical

Nov 17, 2008 - Geoffrey P. McDermott , Jessica M. Terry , Xavier A. Conlan , Neil W. Barnett ... Geoffrey P. McDermott , Philip Jones , Neil W. Barnet...
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Anal. Chem. 2008, 80, 9817–9821

Chemiluminescence Detector with a Serpentine Flow Cell Jessica M. Terry,† Jacqui L. Adcock,†,§ Don C. Olson,‡ Duane K. Wolcott,‡ Cassie Schwanger,‡ Lauren A. Hill,† Neil W. Barnett,† and Paul S. Francis*,† School of Life and Environmental Sciences, Deakin University, Geelong, Victoria 3217, Australia, and Global FIA, P.O. Box 480, Fox Island, Washington 98333 We present a new chemiluminescence detector, with solution channels that have been machined into a Teflon disk and sealed with a sapphire window. The configuration of the flow cell can be conveniently modified by replacing the Teflon disk. A comparison of some existing and novel designs, using the chemiluminescence reaction of morphine with acidic potassium permanganate and the bioluminescence reaction of ATP with the commercially available “BacTiter-Glo” reagent, has revealed that a serpentine channel allows greater quantities of light to be captured than a spiral channel, due to more efficient mixing of the analyte and reagent solutions within the cell. Chemiluminescence detection has been used extensively in procedures based on flow injection analysis (FIA) and sequential injection analysis (SIA) methodology,1-5 due in part to the excellent sensitivity and wide calibration ranges that have been obtained for diverse classes of analytes. Moreover, the instrumentation is simple, essentially comprising a reaction vessel or conduit with a transparent surface, mounted against a photodetector. The emission of photons from a chemiluminescence reaction is transient and occurs at a rate that is dependent on both the kinetics of the chemical reaction and the physical processes of solution mixing. For the greatest sensitivity, the instrument manifold and the flow cell should be configured to maximize the emission and detection of light when the reacting mixture passes through the cell.2 For relatively fast chemiluminescence reactions, such as the oxidation of organic molecules by acidic potassium permanganate6 or tris(2,2′-bipyridine)ruthe* Corresponding author. Phone: +61 3 5227 1294. Fax: +61 3 5227 1040. E-mail: [email protected]. † Deakin University. ‡ Global FIA. § Present address: RMIT University, GPO Box 2476V, Melbourne, Victoria 3001, Australia. (1) Fletcher, P.; Andrew, K. N.; Calokerinos, A. C.; Forbes, S.; Worsfold, P. J. Luminescence 2001, 16, 1–23. (2) Calokerinos, A. C.; Palilis, L. P. In Chemiluminescence in Analytical Chemistry; Garcı´a-Campan ˜a, A. M., Baeyens, W. R. G., Eds.; Marcel Dekker: New York, 2001; pp 321-348. (3) Lenehan, C. E.; Barnett, N. W.; Lewis, S. W. Analyst 2002, 127, 997–1020. (4) Mervartova´, K.; Pola´sˇek, M.; Martı´nez Calatayud, J. J. Pharm. Biomed. Anal. 2007, 45, 367–381. (5) Garcı´a-Campan ˜a, A. M.; Lara, F. J. Anal. Bioanal. Chem. 2007, 387, 165– 169. (6) Adcock, J. L.; Francis, P. S.; Barnett, N. W. Anal. Chim. Acta 2007, 601, 36–67. 10.1021/ac801842q CCC: $40.75  2008 American Chemical Society Published on Web 11/17/2008

nium(III),7 the analyte and reagent solutions should merge at (or close to) the point of detection. In addition, the dead volume should be minimized to ensure rapid rinsing of the cell between analyses. A variety of chemiluminescence detection cells have been described.8-17 The most commonly used configuration consists of a coil of glass or polymer tubing (normally 0.5-1.0 mm i.d.) mounted against a photomultiplier tube within a light-tight container. Solutions merge at a T- or Y-shaped junction shortly before entering the coil.8,9 However, this design has several limitations: (i) the walls of the tubing are curved, and therefore most of the surface is not flat against the photodetector window, (ii) polymer tubing is often translucent rather than totally transparent, (iii) mixing is initiated before the reacting mixture enters the coil, and (iv) the internal diameter of the tubing is limited by availability. Alternatively, in the fountain flow cell, the reacting mixture enters the center of an open, shallow cylindrical space and drains into a ring-shaped well around the edge, which contains the outlet hole.13,18 This configuration allows a greater volume of solution to be in contact with a flat surface facing the photodetector. Similarly, detection cells with spiral channels have been created by etching or machining channels into polymer blocks or chips.19-23 Another design, referred to as the bundle cell,16 consists of a bundle of PTFE tubing packed into a plastic cuvette. This configuration was found to be 50% more efficient than a “spiral cell” composed of a coil of the same PTFE tubing. However, the first turn of the coil used in that particular study had a diameter (7) Gorman, B. A.; Francis, P. S.; Barnett, N. W. Analyst 2006, 131, 616–639. (8) Burguera, J. L.; Townshend, A.; Greenfield, S. Anal. Chim. Acta 1980, 114, 209–214. (9) Abbott, R. W.; Townshend, A. Anal. Proc. 1986, 23, 25–26. (10) Veazey, R. L.; Nieman, T. A. J. Chromatogr. 1980, 200, 153–162. (11) Pe´rez Pavo´n, J. L.; Rodriguez Gonzalo, E.; Christian, G. D.; Ruzicka, J. Anal. Chem. 1992, 64, 923–929. (12) Preuschoff, F.; Spohn, U.; Blankenstein, G.; Mohr, K.-H.; Kula, M.-R. Fresenius’ J. Anal. Chem. 1993, 346, 924–929. (13) Tucker, D. J.; Toivola, B.; Pollema, C. H.; Ruzicka, J.; Christian, G. D. Analyst 1994, 119, 975–979. (14) Hu, X.; Takenaka, N.; Kitano, M.; Bandow, H.; Maeda, Y.; Hattori, M. Analyst 1994, 119, 1829–1833. (15) Martelli, P. B.; Reis, B. F.; Arau´jo, A. N.; Conceic¸˜ao, M.; Montenegro, B. S. M. Talanta 2001, 54, 879–885. (16) Campı´ns-Falco´, P.; Tortajada-Genaro, L. A.; Bosch-Reig, F. Talanta 2001, 55, 403–413. (17) Llorent-Martı´nez, E. J.; Ortega-Barrales, P.; Molina-Dı´az, A. Anal. Chim. Acta 2006, 580, 149–154. (18) Scudder, K. M.; Pollema, C. H.; Ruzicka, J. Anal. Chem. 1992, 64, 2657– 2660.

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of 1 cm, leaving a relatively large empty space in the center of the coil compared to similar flow cells constructed by other researchers. Nevertheless, that study16 highlighted the potential of repeated sharp deviations in a narrow conduit to improve mixing efficiency. In this paper, we present a detector designed to maximize both the generation and transmission of light from chemiluminescence reactions. The key component of the new detector is a thin Teflon disk with grooves machined into one side. The Teflon disk is placed against a sapphire (Al2O3) window to form a flow channel with a flat transparent wall for efficient transmission of light to the photomultiplier tube. The channel configuration can be conveniently modified by replacing the Teflon disk, and we have explored a novel serpentine design that incorporates 114 reversing turns to enhance mixing efficiency.24 EXPERIMENTAL SECTION Chemiluminescence Detectors. The general design of the new “GloCel” chemiluminescence detector (Global FIA, Fox Island, WA) is depicted in Figure 1. To set the path of solution flow within the cell, a groove was machined into one side of a Teflon disk (Figure 2). Inlet port or ports (at the center of the disk) and an outlet port (at the end of the groove) were drilled through the disk. A sapphire window served as the transparent top surface of the flow cells. The spiral flow cell (Figure 2a) had a channel width and depth of 0.040 in. and a total volume of 275 µL. The single-inlet and double-inlet serpentine cells (Figure 2, parts b and c) had channel widths of 0.030 in. and depths of 0.035 in. The serpentine design contained 114 turns. The volume of these cells was 245 and 235 µL, respectively. After the cell was fastened together by screwing in the black PEEK cell cap, a photomultiplier module (Electron Tubes model P30A-05, ETP, Ermington, NSW, Australia) or photon counting module (Electron Tubes model P23252) was inserted into the holder, and the nut and ferrule were tightened to hold the module against the flow cell window and prevent external light from entering the detector. Cell caps were machined to accept two or three standard 1/4-28 fittings for the singleand double-inlet flow cells, respectively. A “fountain” flow cell was constructed by replacing the Teflon disk with a spacer ring, forming a shallow open cylindrical space. It should be noted that this configuration does not contain the deep ring-shaped well described by Ruzicka and co-workers.13,18 A conventional flow cell was constructed by mounting a coil (3 cm diameter) of transparent PTFE tubing (0.8 mm i.d.; DKSH, Caboolture, Queensland, Australia) on a thin metal sheet (3.5 cm (19) Economou, A.; Clark, A. K.; Fielden, P. R. Anal. Commun. 1998, 35, 389– 390. (20) Piza`, N.; Miro´, M.; de Armas, G.; Becerra, E.; Estela, J. M.; Cerda`, V. Anal. Chim. Acta 2002, 467, 155–166. (21) Kiba, N.; Tokizawa, T.; Kato, S.; Tachibana, M.; Tani, K.; Koizumi, H.; Edo, M.; Yonezawa, E. Anal. Sci. 2003, 19, 823–827. (22) Lewis, S. W.; Francis, P. S.; Lim, K. F.; Jenkins, G. E. Anal. Chim. Acta 2002, 461, 131–139. (23) Magalha˜es, L. M.; Segundo, M. A.; Reis, S.; Lima, J. L. F. C.; Estela, J. M.; Cerda`, V. Anal. Chem. 2007, 79, 3933–3939. (24) Ruzicka and co-workers (refs 13 and 18) have occasionally referred to conventional flow cells consisting of a coil of tubing as “serpentine”, but the cells did not have a series of reversing turns. Veazey and Nieman (ref 10) described a “serpentine” flow cell comprising a linear (rather than spiral) arrangement of seven reversing turns, which they constructed from 1.5 mm i.d. glass tubing.

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Figure 1. Chemiluminescence detector consisting of (A) flow cell, (B) main body to house the photomultiplier tube (PMT) module and position it against the flow cell window, and (C) nut and ferrule to lock in and light-seal the PMT module. Flow cell components: (D) flat gasket, (E) sapphire window, (F) Teflon disk with machined channels, (G) light-seal “O”-ring, and (H) back plate (single-inlet design shown), which is fastened to the main detector body to seal the flow cell.

Figure 2. Teflon disks with machined channels: (a) spiral, (b) serpentine, and (c) double-inlet serpentine.

× 6 cm). The tubing at the center of the coil passed through a small slit in the sheet. The photomultiplier module was mounted flush against the coil, and the components were encased in a lighttight housing. Instrument Manifolds. The FIA manifold (Figure 3a) was constructed from a Gilson Minipuls 3 peristaltic pump (John Morris Scientific, Balwyn, Victoria, Australia) with bridged PVC pump tubing (1.02 mm i.d.; DKSH), black manifold tubing (0.76 mm i.d., Global FIA), and Valco six-port injection valve (SGE, Ringwood, Victoria, Australia) with 70 µL injection loop. In the case of the single-inlet cells, a custom-made Y-fitting was screwed into the inlet port. In the case of the conventional approach, a plastic T-piece was connected to the coil by slipping a small piece of silicone tubing (1 mm i.d.; DKSH) over both tubing and fitting. In both cases, the distance from the solution

Figure 3. (a) Flow injection analysis, (b) sequential injection analysis, and (c) direct aspiration manifolds for the chemiluminescence detection of morphine. (d) Zone-fluidics manifold for the bioluminescence detection of ATP (pp, peristaltic pump; s, six-port injection valve; d, detector; p, milliGAT pump; h, holding coil; v, multiposition valve; 1-5, sample/reagent solutions; w, waste).

confluence point to the beginning of the coil was approximately 1 cm. Signal output from the photomultiplier module was documented with a type 3066 chart recorder (Yokogawa Hokushin Electric, Tokyo, Japan). Other instrument manifolds were constructed using milliGAT pumps (model CP-DSM-GF, Global FIA), a 10-port multiposition valve (model C25Z, Valco), PTFE or PFA tubing (Global FIA), and standard 1/4-28 and 10-32 fittings (Global FIA). Software for instrument control and data acquisition was developed using the LabVIEW platform. Reagents. The permanganate reagent was prepared daily by dissolving potassium permanganate (Chem-Supply, Gillman, South Australia, Australia) in 1% (m/v) sodium polyphosphate (Aldrich, St. Louis, MO) and adjusting the pH to 2.5 by the dropwise addition of concentrated sulfuric acid (Merck, Kilsyth, Victoria, Australia). Morphine was obtained from GlaxoSmithKline (Port Fairy, Victoria, Australia). The BacTiter-Glo reagent and ATP solutions (Promega, Madison, WI) were stored at -20 °C and prepared fresh daily. RESULTS AND DISCUSSION Chemiluminescence Detection of Morphine. The reaction of morphine with acidic potassium permanganate was selected for the comparison of different flow cells because it has been used extensively as a method of detection for flow analysis and highperformance liquid chromatography (HPLC)25 and is a representative example of the relatively fast chemiluminescence reactions between strong oxidizing agents and organic analytes.6 The (25) Francis, P. S.; Adcock, J. L.; Costin, J. W.; Purcell, S. D.; Pfeffer, F. M.; Barnett, N. W. J. Pharm. Biomed. Anal. 2008, 48, 508–518.

Figure 4. Relative response for the chemiluminescence reaction of morphine (1 × 10-7 M) with acidic potassium permanganate using (a) FIA or (b) SIA methodology.

emission from this particular reaction reaches maximum intensity within a few seconds under stopped-flow conditions.26 With the use of FIA methodology (Figure 3a), morphine standards (1 × 10-8 to 1 × 10-5 M) were injected into a water carrier stream (line 2), which merged with the permanganate reagent (line 1). As shown in Figure 4a, the chemiluminescence intensities obtained using the spiral, serpentine, or double-inlet serpentine flow cells were similar to those obtained using the PTFE coil. The single-inlet serpentine cell gave the greatest signals, generally 6-11% higher than either the coil or spiral cells. The fountain flow cell was found to be inferior in terms of chemiluminescence intensity and precision; the relative standard deviation for 10 replicate injections of 1 × 10-7 M morphine (9.6%) was much greater than that of the other configurations (all